Difference between revisions of "Part:BBa K2332312"

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<center>'''Diagram 1: Cell Aggregation Chart w/ and w/o Ca<sup>2+</sup>'''</center>
 
<center>'''Diagram 1: Cell Aggregation Chart w/ and w/o Ca<sup>2+</sup>'''</center>
  

Revision as of 11:38, 9 October 2017


E-cadherin (Preproprotein, Mus Musculus)

E-cadherin (Preproprotein, Mus Musculus)
Function Cell-Cell Adhesion
Use in Mammalian cells
Chassis Tested Chinese Hamster Ovary (CHO)
Abstraction Hierarchy Part
Related Device BBa_K2332313
RFC standard RFC10 & RFC23 compatible
Backbone pSB1C3
Submitted by [http://2017.igem.org/Team:UCL UCL iGEM 2017]

This gene encodes E-cadherin, a calcium-dependent cell adhesion molecule that functions in the establishment and maintenance of epithelial cell morphology during embryongenesis and adulthood. The encoded preproprotein undergoes proteolytic processing to generate a mature protein.




Usage and Biology

Cell-cell junctions come in many forms and can be regulated by a variety of different mechanisms. The best understood and most common are the two types of cell-cell anchoring junctions which employ cadherins to link the cytoskeleton of one cell with that of its neighbour. Their primary function is to resist the external forces that pull cells apart. At the same time, however, they need to dynamic and adaptable, so that they can be altered or rearranged when tissues are remodelled or repaired or when there are changes in the forces acting on them.

Figure 1: Adherens Junction - Cadherin Mediated Cell-Cell Adhesion.

(A) Adherens junctions, in the form of adhesion belts, between epithelial cells in the small intestine. The beltlike junction encircles each of the interacting cells. Its most obvious feature is a contractile bundle of actin filaments running along the cytoplasmic surface of the junctional plasma membrane. (B) Some of the molecules that form an adherens junction. The actin filaments are joined from cell to cell by transmembrane adhesion proteins called cadherins. (Alberts B. Molecular Biology of the Cell. 6th ed. New York: Garland Science; 2015)


Cadherins are a diverse family of adhesion molecules that fulfil these requirements. They are present in all multicellular animals whose genomes have been analysed. Other eukaryotes, including fungi and plants, lack cadherins, and they are also absent from bacteria and archaea. Cadherins therefore seem to be part of the essence of what it is to be an animal.

The cadherins take their name from their dependence on Ca2+ ions: removing Ca2+ from the extracellular medium causes adhesions mediated by cadherins to come apart. The first three cadherins to be discovered were named according to the main tissues in which they were found: - E-cadherin is present on many types of epithelial cells; - N-cadherin on nerve, muscle and lens cells; - P-cadherin on cells in the placenta and epidermis. All are also found in other tissues. These and other classical cadherins are closely related in sequence throughout their extracellular and intracellular domains.

Binding between cadherins is generally homophilic. That means cadherin molecules of a specific subtype on one cell bind to cadherin moleculs of the same or closely related subtype on adjacent cells. All members of the superfamily have an extracellular portion consisting of several copies of the extracellular cadherin (EC) domain. Homophilic binding occurs at the N-terminal tips of the cadherin molecules - the cadherin domains that lie furthest from the membrane. These terminal domains each form a knob and a nearby pocket, and teh cadheirn molecules protruding from opposite cell membranes bind by insertion of the knob of one domain into the pocket pf the other.



Figure 2: Molecular Model of E-cadherin (Alberts B. Molecular Biology of the Cell. 6th ed. New York: Garland Science; 2015)


Each cadherin domain forms a more-or-less rigid unit, joined to the next cadherin domain by a hing. Ca2+ ions bind to sites near each hinge and prevent it from flexing, so that the whole string of cadherin domains behaves as a rigid and slightly curved rod. When Ca2+ is removed, the hinges can flex, and the structure becomes floppy. At the same time, the conformation at the N-terminus is thought to change slightly, weakening the binding affinity for the matching cadherin molecule on the opposite cell.

The cadherins form homodimers in the plasma membrane of each interacting cell. The extracellular domain of one cadherin dimer binds to the extracellular domain of an identical cadherin dimer on the adjacent cell. The intracellular tails of the cadherins bind to anchor proteins that tie them to actin filaments. These anchor proteins include α-catenin, β-catenin, γ-catenin (also called plakoglobin), α-actinin, and vinculin.

UCL iGEM 2017 believes that cadherin proteins will be powerful modulators for efficient tissue engineering. We therefore investigated first the properties of one classical cadherin (E-cadherin, BBa K2332312) and then tried to make it light-responsive.

For more information on cell-cell junctions and cadherins see Alberts B., Molecular Biology of the Cell. 6th ed., Ch.19, New York: Garland Science; 2015.




E-Cadherin Entries in the Registry

UCSF iGEM 2011 has created a BioBrick of only the extracellular domain of E-Cadherin (Mouse) BBa_K644000 but no BioBrick encoding the full E-cadherin protein has been submitted until now. BBa_K644000 also lacked detailed characterisation and the source was imprecise. Furthermore, we know now that E-cadherin requires interaction of its cytosolic domain for the production of stable cell-cell connections. (see Alberts 6th Ed. 2015, Ch. 19, p. 1040).


Experimental approach

Vector Considerations

For testing this coding part we used pcDNA3, a standard mammalian expression plasmid, as a vector. We, thereby, created BBa_K2332313, our E-cadherin gene flanked by a CMV promoter and a bGH poly(A) tail. The pre-existing 5'- and 3'-UTR and the strong promoter ensure efficient expression of E-cadherin after transfection.

Chassis Considerations

Choosing the correct chassis for your experiments is of equal importance to choosing the correct gene.

Since we wanted to test cell-cell aggregation induced by the E-cadherin gene, we therefore chose a mammalian cell line that naturally does not express E-cadherin and is commonly used in cadherin research, Chinese Hamster Ovary (CHO) cells. Even though they naturally lack E-cadherin expression they still maintain alpha- and beta-catenin expression, the two proteins that are essential for E-cadherin's connection to the actin cortex of the cell.


Experimental Setup

Choosi


Results

Choosi

Diagram 1: Cell Aggregation Chart w/ and w/o Ca2+

.

Well Contents Single Cells Single Cells Average Aggregated Cells Aggregated Cells Average Ratio single:aggregated
A Cells + superfect + plasmid 163, 245, 251 220 195, 242, 311 249 0.88
B Cells + superfect + plasmid + calcium 239, 237, 213 230 251, 342, 477 356 0.65
C CaCl2 only 163, 245, 251 / /
D Control cells 236, 173, 290, 185 221 157, 145, 116, 258 169 1.3
E Control cells + calcium 187, 220, 142 183 137, 219, 136 164 1.1
F Untreated cells 549, 385, 554 496 500, 397, 582 493 1.0

Table 1: Cell Aggregation Results w/ and w/o Ca2+


Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    INCOMPATIBLE WITH RFC[12]
    Illegal NheI site found at 2550
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal BamHI site found at 752
    Illegal BamHI site found at 828
    Illegal BamHI site found at 944
    Illegal BamHI site found at 1868
    Illegal BamHI site found at 2170
    Illegal XhoI site found at 1552
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    INCOMPATIBLE WITH RFC[25]
    Illegal NgoMIV site found at 208
  • 1000
    INCOMPATIBLE WITH RFC[1000]
    Illegal BsaI site found at 65
    Illegal BsaI site found at 465
    Illegal BsaI site found at 872
    Illegal BsaI site found at 1414
    Illegal BsaI.rc site found at 306


This gene was given to the UCL iGEM team 2017 by Prof. Stephen Price (UCL, not part of iGEM) after we searched for cadherin proteins suitable for our project. However, no sequence was known of the plasmid we were given and we sequenced the plasmid ourselves. Consecutive BLAST analysis of the results showed a 99% similarity with Mus musculus cadherin 1 (Cdh1), mRNA: NCBI Reference Sequence: NM_009864.3, NCBI.

Three silent mutations were added into the sequence via side directed mutagenesis in order to remove one EcoRI and two PstI sites. Afterwards we sequence confirmed the entire gene.

Figure 3: Protein BLAST Results from E-cadherin (Link).

Cadherin Prodomain Like - Cadherin proteins are activated through cleavage of a prosequence in the late Golgi. This prevents cadherin aggregation in the early stage of the secretory pathway. This domain corresponds to the folded region of the prosequence, and is termed the prodomain. The prodomain shows structural resemblance to the cadherin domain, but lacks all the features known to be important for cadherin-cadherin interactions.

Cadherin Repeat-Like Domain- The cadherin repeat domains occur as tandem repeats in the extracellular regions, which are thought to mediate cell-cell contact when bound to calcium. They play numerous roles in cell fate, signalling, proliferation, differentiation, and migration; members include E-, N-, P-, T-, VE-, CNR-, proto-, and FAT-family cadherin, desmocollin, and desmoglein, a large variety of domain architectures with varying repeat copy numbers. Cadherin-repeat containing proteins exist as monomers, homodimers, or heterodimers. This family also includes the cadherin-like repeats of extracellular alpha-dystroglycan.

Cadherin Cytoplasmic Region- Cadherins are vital in cell-cell adhesion during tissue differentiation. Cadherins are linked to the cytoskeleton by catenins. Catenins bind to the cytoplasmic tail of the cadherin. Cadherins cluster to form foci of homophilic binding units. A key determinant to the strength of the binding that it is mediated by cadherins is the juxtamembrane region of the cadherin. This region induces clustering and also binds to the protein p120ctn.

Functional Parameters

Protein data table for BioBrick BBa_ automatically created by the BioBrick-AutoAnnotator version 1.0
Nucleotide sequence in RFC 10: (underlined part encodes the protein)
 AGCTTGGTACCTCCACCATGGGAGCC ... GAGGACGACTAGA
 ORF from nucleotide position 18 to 2669 (excluding stop-codon)
Amino acid sequence: (RFC 25 scars in shown in bold, other sequence features underlined; both given below)

101 
201 
301 
401 
501 
601 
701 
801 
MGARCRSFSALLLLLQVSSWLCQELEPESCSPGFSSEVYTFPVPEGHLERGHVLGRVRFEGCTGRPRTAFFSEDSRFKVATDGTITVKRHLKLHKLETSF
LVRARDSSHRELSTKVTLKSMGHHHHRHHHRDPASESNPELLMFPSVYPGLRRQKRDWVIPPISCPENEKGEFPKNLVQIKSNRDKETKVFYSITGQGAD
KPPVGVFIIERETGWLKVTQPLDREAIAKYILYSHAVSSNGEAVEDPMEIVITVTDQNDNRPEFTQEVFEGSVAEGAVPGTSVMKVSATDADDDVNTYNA
AIAYTIVSQDPELPHKNMFTVNRDTGVISVLTSGLDRESYPTYTLVVQAADLQGEGLSTTAKAVITVKDINDNAPVFNPSTYQGQVPENEVNARIATLKV
TDDDAPNTPAWKAVYTVVNDPDQQFVVVTDPTTNDGILKTAKGLDFEAKQQYILHVRVENEEPFEGSLVPSTATVTVDVVDVNEAPIFMPAERRVEVPED
FGVGQEITSYTAREPDTFMDQKITYRIWRDTANWLEINPETGAIFTRAEMDREDAEHVKNSTYVALIIATDDGSPIATGTGTLLLVLLDVNDNAPIPEPR
NMQFCQRNPQPHIITILDPDLPPNTSPFTAELTHGASVNWTIEYNDAAQESLILQPRKDLEIGEYKIHLKLADNQNKDQVTTLDVHVCDCEGTVNNCMKA
GIVAAGLQVPAILGILGGILALLILILLLLLFLRRRTVVKEPLLPPDDDTRDNVYYYDEEGGGEEDQDFDLSQLHRGLDARPEVTRNDVAPTLMSVPQYR
PRPANPDEIGNFIDENLKAADSDPTAPPYDSLLVFDYEGSGSEAASLSSLNSSESDQDQDYDYLNEWGNRFKKLADMYGGGEDD*
Sequence features: (with their position in the amino acid sequence, see the list of supported features)
RFC25 scar (shown in bold): 63 to 64, 195 to 196
Amino acid composition:
Ala (A)61 (6.9%)
Arg (R)45 (5.1%)
Asn (N)43 (4.9%)
Asp (D)72 (8.1%)
Cys (C)9 (1.0%)
Gln (Q)32 (3.6%)
Glu (E)67 (7.6%)
Gly (G)52 (5.9%)
His (H)21 (2.4%)
Ile (I)44 (5.0%)
Leu (L)75 (8.5%)
Lys (K)35 (4.0%)
Met (M)13 (1.5%)
Phe (F)30 (3.4%)
Pro (P)60 (6.8%)
Ser (S)53 (6.0%)
Thr (T)65 (7.4%)
Trp (W)8 (0.9%)
Tyr (Y)26 (2.9%)
Val (V)73 (8.3%)
Amino acid counting
Total number:884
Positively charged (Arg+Lys):80 (9.0%)
Negatively charged (Asp+Glu):139 (15.7%)
Aromatic (Phe+His+Try+Tyr):85 (9.6%)
Biochemical parameters
Atomic composition:C4330H6765N1179O1382S22
Molecular mass [Da]:98156.7
Theoretical pI:4.67
Extinction coefficient at 280 nm [M-1 cm-1]:82740 / 83303 (all Cys red/ox)
Plot for hydrophobicity, charge, predicted secondary structure, solvent accessability, transmembrane helices and disulfid bridges 
Codon usage
Organism:E. coliB. subtilisS. cerevisiaeA. thalianaP. patensMammals
Codon quality (CAI):good (0.70)good (0.70)acceptable (0.59)good (0.68)excellent (0.83)good (0.79)
Alignments (obtained from PredictProtein.org)
   There were no alignments for this protein in the data base. The BLAST search was initialized and should be ready in a few hours.
Predictions (obtained from PredictProtein.org)
   There were no predictions for this protein in the data base. The prediction was initialized and should be ready in a few hours.
The BioBrick-AutoAnnotator was created by TU-Munich 2013 iGEM team. For more information please see the documentation.
If you have any questions, comments or suggestions, please leave us a comment.


References

1. 2. 3. 4.

5.